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$\mathcal{F}$ itself becomes an $\mathcal{F}$ -category in the usual way. Its tight morphisms are just the morphisms in the underlying ordinary category $\mathcal{F}$ , while its loose morphisms are simply functors between the loose parts (the codomains of the full embeddings).

$\mathcal{F}$ -functors and $\mathcal{F}$ -transformations

Definition

An $\mathcal{F}$ -functor $F:\mathbb{A} \to \mathbb{B}$ is a 2-functor $F_\lambda:\mathcal{A}_\lambda \to \mathcal{B}_\lambda$ sends tight 1-cells to tight 1-cells, i.e. such that it co/restrcts to a 2-functor $\mathcal{A}_\tau \to \mathcal{B}_\tau$ .

Definition

An $\mathcal{F}$ -natural transformation $\alpha:F \to G$ is a 2-natural transformation $F_\tau \to G_\tau$ , i.e. a 2-natural transformation $F \to G$ whose components are all tight.

$\mathcal{F}$ -weighted limits

The general machinery of enriched category theory applied to $\mathcal{F}$ gives us a notion of weighted limit. Note first that an $\mathcal{F}$ -enriched diagram in an $\mathcal{F}$ -category is a diagram of morphisms in which some are required to be tight, and others are not (but could “accidentally” be tight).

In general, a weighted limit of such a diagram in a (strict) $\mathcal{F}$ -category is a weighted (strict) 2-limit in its 2-category of loose morphisms, with the property that certain specified projections from the limit object are tight and “jointly detect tightness”, in the sense that a morphism into the limit is tight if and only if its composites with all of the specified projections are tight. Details and examples can be found in (LS).

One of the most important things about $\mathcal{F}$ -categories is that they allow us to define the classes of rigged limits, which are the $\mathcal{F}$ -weighted limits that are created by the forgetful functors from the various $\mathcal{F}$ -categories of algebras and strict/pseudo/lax/colax morphisms over a 2-monad (or an $\mathcal{F}$ -monad).

$\mathcal{F}$ -weights

Let $\mathbb{F}$ be $\mathcal{F}$ considered as self-enriched. In (LS) (where all that follows is taken from), it is shown that an $\mathcal{F}$ -weight $\Phi:\mathbb{D} \to \mathbb{F}$ is given by the following data:

2-functors $\Phi_\tau : \mathcal{D}_\tau \to \mathbf{Cat}$ and $\Phi_\lambda : \mathcal{D}_\lambda \to \mathbf{Cat}$ ,
a 2-natural transformation $\varphi : \Phi_\tau \to \Phi_\lambda J_{\mathbb{D}}$ whose components are full embeddings (i.e. injective-on-objects?, fully faithful functors)

Here $J_\mathbb{D}$ denotes the identity-on-objects, faithful and locally fully faithful? inclusion of the tight 2-category associated to $\mathbb{D}$ into its loose 2-category.

Representable weights are easily constructed. Let $S:\mathbb{D} \to \mathbb{A}$ be an $\mathcal{F}$ -diagram, i.e. an $\mathcal{F}$ -functor. Any chosen $A \in \mathbb{A}$ induces an $\mathcal{F}$ -weight on $\mathbb{D}$ given by

Now a $\Phi$ -weighted limit for $S$ , $\lim^\Phi S$ , is characterized by the isomorphism

\mathbb{A}(A, \lim^\Phi S) \cong [\mathbbf{D},\mathbb{F}](\Phi, \mathbb{A}(A,S))

One can prove (by an easy characterization of the $\mathcal{F}$ -category on the right) this amounts to three conditions:

$\lim^\Phi S$ is a 2-limit in the 2-category $\mathcal{A}_\lambda$ ,
for any $w \in \Phi_\tau(D)$ , the projection $p_D^w : \lim^\Phi S \to S(D)$ is tight,
for any $h:A \to \{\Phi,S\}$ , $h$ is tight as soon as for each $w \in \Phi_\tau(D)$ , $h p_D^w$ is tight.

The third condition is succinctly expressed by saying the family $\{p_D^w\}_{D \in \mathbb{D}, w \in \Phi_\tau(D)}$ jointly detects tightness.

Neural Tangent Kernel
Rupak Chatterjee, Ting Yu: Generalized Coherent States, Reproducing Kernels, and Quantum Support Vector Machines, Quantum Information and Communication 17 15&16 (2017) 1292 [arXiv:1612.03713, doi:10.26421/QIC17.15-16]
Quantum Machine Learning in Feature Hilbert Spaces
Quantum support vector machine for big data classification
Supervised learning with quantum enhanced feature spaces

On non-abelian (parafermionic) defect anyons associated with superconducting islands inside abelian fractional quantum Hall systems:

Netanel H. Lindner, Erez Berg, Gil Refael, Ady Stern: Fractionalizing Majorana fermions: non-abelian statistics on the edges of abelian quantum Hall states, Phys. Rev. X 2 (2012) 041002 [arXiv:1204.5733, doi:10.1103/PhysRevX.2.041002]
David J. Clarke, Jason Alicea, Kirill Shtengel: Exotic non-Abelian anyons from conventional fractional quantum Hall states, Nature Communications 4 1348 (2013) [doi: 10.1038/ncomms2340, arXiv:1204.5479]
Abolhassan Vaezi: Fractional topological superconductor with fractionalized Majorana fermions, Phys. Rev. B 87 (2013) 035132 [doi:10.1103/PhysRevB.87.035132, arXiv:1204.6245]
Roger S. K. Mong, David J. Clarke, Jason Alicea, Netanel H. Lindner, Paul Fendley, Chetan Nayak, Yuval Oreg, Ady Stern, Erez Berg, Kirill Shtengel, Matthew P. A. Fisher: Universal Topological Quantum Computation from a Superconductor-Abelian Quantum Hall Heterostructure, Phys. Rev. X 4 (2014) 011036 [arXiv:1307.4403, doi:10.1103/PhysRevX.4.011036]
Younghyun Kim, David J. Clarke, Roman M. Lutchyn: Coulomb Blockade in Fractional Topological Superconductors, Phys. Rev. B 96 (2017) 041123 [arXiv:1703.00498, doi:10.1103/PhysRevB.96.041123]
Luiz H. Santos, Taylor L. Hughes: Parafermionic Wires at the Interface of Chiral Topological States, Phys. Rev. Lett. 118 (2019) 136801 [doi:10.1103/PhysRevLett.118.136801]
Luiz H. Santos: Parafermions in Hierarchical Fractional Quantum Hall States, Phys. Rev. Research 2 (2020) 013232 [arXiv:1906.07188, doi:10.1103/PhysRevResearch.2.013232]

nLab Sandbox

ℱ\mathcal{F}-functors and ℱ\mathcal{F}-transformations

Definition

Definition

ℱ\mathcal{F}-weighted limits

ℱ\mathcal{F}-weights

$\mathcal{F}$ -functors and $\mathcal{F}$ -transformations

$\mathcal{F}$ -weighted limits

$\mathcal{F}$ -weights